Air brake



April 7,- 1942;

D. A. KALOSHIN AIR BRAKE Filed se t. 27, 1940 5 Sheets-Sheet l INVENTOR. .DMITR/ ANDRE/EWCH luosl-mv April 7, 1942. D. A. KALOSHIN 2,278,700

AIR BRAKE Filed Sept. 2'7, 1940 5 Sheets-Sheet 3 M....--.--- 5 E a m m \DMWMV M W lbw R g m m in a mwk mm April 7, 1 942.

D. A. KAL OSHIN AIR BRAKE Filed Sept. 27, 1940 5 Sheets-Sheet 4 NN IS w mar 4 I IluJ nQN pom VNN wNN 1NVENTOR. .DM/TR/ ANDRE Ewen K/uosr-mv Patented Apr. 7, 1942 I 1' AIR BRAKE Dmitri Andreievich Kaloshin, San Francisco,

Calif., assignor of one-half to Paul Pimenofi and Pelagea Lubushkin. both of San Francisco,

Calif.

Application September 27, 1940, Serial No. 358,625

11 Claims.

This invention relates to air brakes. Air brakes presently in general use on railroad cars and engines, buses and other vehicles are operated by compressed air at certain standard pressure, and each vehicle is equipped with a supply tank in which the compressed air is stored for the purpose of operation of the brakes. The air at said standard pressure is supplied to the supply tank by the main line to which all the supply tanks are connected. The present brakes are so designed that the compressed air may be supplied to the supply tanks only when the brakes are not in operation, and therefore if the brakes are applied for a comparatively long period of time, the supply tank may become exhausted, and thereupon the brakes shall become inoperative.

The air brakes are actuated by brake actuating mechanisms, which are also connected to the main line, when the air pressure in the main line drops from the standard pressure to a certain operating pressure. It takes an appreciable period of time to reduce the air pressure in said main line to the operating pressure if the line is of considerable length. To release the brakes, the air pressure in the main line is increased to the standard pressure, whereupon the actuating mechanism releases the brakes.

In the present air brakes the release of the brakes is not sufficiently elastic and the brakes cannot be released to a desired degree and held in such position for a desired length of time. Furthermore, braking power is equally applied on all cars in a train, whereas it is desirable to vary the application of braking power depending upon the character of a car and speed of a train.

It is the object of this invention to provide an air brake which is adapted to supply the compressed air to supply tanks from the main line when the brakes are applied, if so desired.

Another object of this invention is to accelcrate the application of the brakes and make the same practically simultaneous for all the cars in a train. I

Another object of this invention is to provide a means for gradual intermittent release of the brakes to any desired degree, said means being adapted to hold said brakes in any desired position for any length of time.

Another object of this invention is to provide means for individual adjustment of application of brakes on the cars, so as to suit various load and speed conditions.

Other objects and advantages will appear as the specification proceeds and the particular features of the device will be specifically pointed out in the appended claims.

I In this specification and the annexed drawings, the invention is illustrated in the form considered to be the best, but it is to be understood, that the invention is not limited to such form; and it is also to be understood that in and by the claims following the description, it is desired to cover the invention in whatsoever form it may be embodied.

In the drawings:

Fig. 1 is a diagrammatic view showing the relation of various parts and mechanisms in the air brake which constitutes the subject-matter of this invention.

Fig. 2 is a diagrammatic view showing the operating valves used in connection with said air brake.

Fig. 3 is a plan view of a brake actuating mechanism.

Fig. 4 is a side. view of said mechanism looking in the direction of the arrow 4 on the Fig. 3.

Fig. 5 is a sectional view, partly. in elevation, taken along the line 55 of the Fig. 3.

Fig. 6 is a sectional view, partly in elevation, taken along the line 6-6 of the Fig. 3.

Fig. 7 is a section through a sliding valve taken near the sliding surface thereof.

Fig. 8 is a plan view of the level portion of a bushing upon which portion the above mentioned valve is adapted to slide.

Fig. 9 is a sectional view, partly in elevation,

taken along the line 9--9 of the Fig. 3.

Fig. 10 is a section through a second sliding valve taken near the sliding surface thereof.

Fig. 11 is a plan View of the level portion of a second bushing upon which portion the above mentioned second sliding valve is adapted to slide.

Figs. 12, 13 and 14 are central cross-sections through a stop-cock and a bushing, showing various positions of the stop-cock, and

Figs. 15, 16, 17 and 18 are diagrammatic illustrations of the positions of various parts of the air brake during the partial'and full application of the brakes, supply of air when the brakes are applied, and gradual intermittent release of the brakes, respectively.

My air brake consists of an actuating mechanism I attached to a vehicle by a bracket I and connected with a main line 2 by a conduit 3, and a supply tank 4, and a brake mechanism 6 communicating with said mechanism by the pipes 5 and 1 respectively.

The brake mechanism 6 consists of a cylinder 8, a piston 9 slidably confined therein, a spring I which yieldably forces said piston 9 into its normal inoperative position, shown in Fig. 1, and a shaft I2 connected to the piston. The shaft I2 by means of links and levers, well known in the art and therefore shown diagrammatically in the drawings, operates the brake shoes I3 and I5, so as to bring the same into frictional engagement with the wheels II, whenever the piston 9 is moved to the left looking at said figure. The piston 9 is actuated by compressed air entering the cylinder 8 through the pipe I and the actuating mechanism I from the supply tank as hereinafter shall be stated in detail.

The actuating mechanism I consists of a first actuator 30, shown in detail in Fig. 6, and a second actuator 3| shown in detail in Figures 9 and 5. The actuators are designed to maintain the supply tank 4 fully supplied with the compressed air, to introduce air at the desired pressure from the supply tank 4 into the cylinder 8, to maintain desired pressure in the cylinder 8, and to release air from said cylinder into the atmosphere.

The actuators 30 and 3| are operated by the variations of the air pressure in the main line 2.

The first actuator 30 consists of a sliding valve chamber 32 formed in a bushing 33 having a level portion 34. The chamber 32 communicates with a piston chamber 36 which in turn communicates with a tank 35. Compressed air is introduced from the main line 2 into said chamber 32 by means of a conduit 3, through a passage 38 in the body of said actuator 30, a hollow semisphere 40 formed at the left end of the chamber 32, looking at Fig. 6.

A piston 4| is slidably confined in the piston chamber 36 and has a valve portion 42 formed integral with said piston on the side thereof facing the bushing 33. The valve portion 42 is adapted to close the bevelled end 44 of said bushing when the piston 4| moves into the extreme left position.

A piston rod 43 is affixed to said piston and terminates with a star-shaped washer 44 adapted to slide in the chamber 32 and keep said piston rod level.

A sliding valve 45 is set, and adapted to'slide, upon the level portion 34 of the bushing 33. The valve 45 has a longitudinal bore 46, one end of which is closed by a lunger 4'! affixed to the piston rod 43, and the other end terminates with a downwardly extending passage 48. Another air passage 50, communicating with the bore 46,

is formed in said valve 45 in close proximity and a in front of the passage 48. An opening is cut through the sides of the valve 45 near the end of the plunger 41 leading thereto, so that whenever said plunger is withdrawn, even slightly, from its innermost position, the compressed air enters from said chamber 32 into said bore 45 and passages 48 and 50.

The valve 45 is held in the sliding contact with the level portion 34 of the bushing 33 by a spring 5| and whenever the piston 4| moves to the right, looking at Fig. 6, the plunger 41 is withdrawn from the bore 46, thus permitting the air to enter the same, and the valve 45 is pushed by the rear portion 48 of the piston rod 43 in the same direction. Whenever the piston 4| moves to the left, the plunger 41 closes the bore 45 and pushes said valve to the left also.

There are, in addition to the passage 48 and 50, two other passages in the valve 45: a passage '52 having a side cavity :53 and a'pa'ssage 55 for the purpose to be hereinafter stated. The latter passage communicates with the chamber 32 by means of a side opening 54.

All the passages are off-set from the center line so as to properly communicate with the apertures 56, 51, 58, 59, 60, 6|, and 62 in the level portion 34 of the bushing 33. Compressed air, being introduced at a standard pressure, preferably 75 pounds, from the main line 2 through the conduit 3 into the chamber 32, forces the piston 4| to move in the extreme right position whereby the plunger 41 opens the bore 46 and the compressed air passes through the same into passage 48, through the aperture in the bushing 33, small passage 65 under said bushing, passage 66, passage 61 into an auxiliary tank 68 and also from the passage 66 through the passage IG into a piston chamber II in which a piston I2 is slidably arranged. The auxiliary tank 68 being connected through the passages 61 and I0 with the chamber 'II increases the capacity of the latter.

A chamber I5 is formed as a continuation of the chamber 1 I, and a third chamber I6 constitutes the continuation of the chamber I5. A second piston TI is slidably confined in the chamber 16 and has a spring pressed valve I9 arranged on the left side, looking on Fig. 6, and in the center thereof, which valve, when opened, as shown in said figure, permits the air to escape from the chamber "I0 into the chamber 15. A spring is yieldably forcing the pistons I2 and TI apart, and an additional spring 8| forces the piston I2 to the right looking at Fig. 6.

Compressed air acts upon the piston '12 and forces the same to the extreme left position, as shown on said Fig. 6. The rod 82 of the piston 12 presses against the stem of the valve I9 and the hollow rod 83 of the piston TI and thereby opens said valve. It also pushes the piston IT to the extreme left position, thus opening a passage for the air from the chamber I6 into the chamber I5 and therefrom through the opening 85 in the wall of the latter chamber into the atmosphere, the purpose of which arrangement shall be hereinafter stated in detail.

The second actuator -3I is located in near pIOX- imity and at the right angle to the first actuator 30 and is connected with the latter by various passages. The construction of the second actuator is substantially the same as that of the first actuator, and, as shown in Fig. 9, it consists of a sliding valve chamber I00 formed by a bushing IGI, having a level portion I02 provided therein upon which a sliding valve I04 is adapted to slide. The chamber I00 communicates with an auxiliary chamber I05 common with a piston chamber I05 within which a piston I06 is slidably confined. The latter carries a rod I08 terminating with a star-shaped washer I09, slidable in the chamber I00, for the purpose of keeping said rod level.

The construction of the sliding valve I04 is substantially identical with that of the valve 45 of the first actuator 30 and has a central longitudinal bore H0, a plunger III adapted to permit or restrict the access of compressed air from the chamber I05, through the cut H2 in the side of said valve, to the bore III]. The latter terminates with a transverse passage II4. The valve I04 also has an inner passage H5 and a side outlet passage H6.

The level portion I02 of the bushing I 0| is formed with a small aperture I I9 connected by a passage I20 with an aperture I2I, apertures I22,

first one is larger than the second one, c'ommuniand I23, and an off-set small aperture I25, desighed to register with passage H6.

The aperture I22 communicates with the passage I21 which is in communication with the passage I28 (see Fig. 6) which latter passage is connected with the chamber 16. The aperture I23 is provided with a passage I extending on the side of the bushing IN and connected with the hollow space I3I which in turn is connected by means of the pipe I with the brake mechanism 6. Therefore the compressed air will flow from the mechanism 6 through the pipe 1, space I3I, passage I30, aperture I23, passage II5, aperture I22, passage I21, passage I28, chamber 16, valve 19, chamber 15 and opening 85 to the atmosphere. This is the first path connecting the mechanism 6 with the atmosphere.

At the same time the compressed air from the brake mechanism 6 passes from the passage I28 (Fig. 6) into an inclined passage I35, and therefrom into another inclined passage I36, through the aperture 6I, side cavity 53, passage 52, aperture 59, and passage I38 leading to the atmosphere. This is the second path connecting the mechanism 6 with the atmosphere.

The hollow space I3I communicates with a mechanism I for individual adjustment of the brake operating mechanism 6. The mechanism I50 consists of a stop-cock I 52, and two valves I53 and I54 operable by the pistons I55 and I56 respectively in the following manner. The space I3I communicates with a chamber I51 in which a piston I55 is adapted to move. A spring I60 holds the piston I55 in upward position, as shown in Fig. 9, as long as no compressed air is introduced into the space I3I' and the chamber I51. In the latter case the piston I55 is forced down, and the air confined in the lower portion of said chamber I51 is exhausted therefrom into the atmosphere through the perforation I6I. Above the piston I55 is located said valve I53 which is shown in raised position in Fig. 9. A small bore I63 is provided between the chambers I64 and I51, so that the air may pass from the first into the second chamber. When the pressure of air in the chamber I51 reaches a certain level the piston I55 is forced down, thereby closing the valve I53 whereupon the air passes through the bore I63. By this arrangement the compressed air is admitted in large quantities at the beginning of the braking operation, thus assuring the quick action of the brakes. But when the brake mechanism has acted, further supply of air to compensate possible leakage is delivered through the bore I63.

The stop-cock I52 is arranged above the chamber I64. It is operated by a handle I66 attached thereto for the purpose of rotating the same and bringing thereby into various positions. The stop-cock has a central bore I61 and apertures I68, I69, I10 and HI leading from said bore to the surface of the stop-cock. The aperture I66, as shown in Figs. 5 and 9 is connected by a passage I13 with the apertures H9 and HI in the portion I02 of the bushing MI, and the aperture I69 is connected by a short passage I15 with the valve chamber I64.

The compressed air from the chamber I00 may pass through the central bore IIO, passage II4, apertures H9 and I2I, passage I13, aperture I68 in the stop-cock I52, bore I61, aperture I69, into the valve chamber I64, from which the air will pass through the small bore I63 and through the valve I53, if the same is opened. As shown in Fig. 9, the apertures I10 and "I of which the cate with a passage I11 leading into the space I3 I, permitting the compressed air to pass'through said apertures into said space.

It is obvious that by rotating the stop-cock I52 in counter clock-wise direction, various combinations of passages and apertures may be obtained, as shown in Figures 12, 13 and 14.

.When the stop-cock I52 is in the position shown in Fig. 9, the discharge of the compressed air into the space I3I and therefrom into the brake mechanism 6 is the largest, as the air is passing through the apertures I10, "I into the.

space I3I directly and through the aperture I69, through the valve I53 and the bore I63, which discharge results in quick action of the brake mechanism. This position of the stop-cock I52 is used on the brakes of the passengercars of th fast trains.

The position of the stop-cock shown in Fig. 12 permits slower discharge of the compressed air therethrough than that previously described, as the aperture I10 is closed, and therefore the action of the brakes is somewhat slower. The stopcock is preferably brought into this position on all passenger cars of an ordinary train.

The position of the stop-cock shown in Fig. 13 permits still less compressed air to pass therethrough as both apertures I10 and "I are cut off,

and therefore the action of the'brakes will be still slower. This position is used in connection with loaded cars of a freight train.

It shall be noted that independent of the position of said stop-cock I 52 heretofore discussed, the air brake mechanism shall operate under the same air pressure, and the said various positions of the stop-cock are used only for the purpose of changing the speed of application of the brakes.

The last position of said stop-cock I52 is shown in Fig. '14 in which all the compressed air is directed through the aperture I69 into a passage I80 communicating with a chamber I8I of the valve I54 and the bottom portion of the piston chamber I82 of the piston I56. In this case the compressed air will force the piston I56 to raise and open the valve I54 through which the air will fill the upper portion of the piston chamber I82 and through the passage I83 will pass into the chamber I64, and therefrom through the bore I63 and through the valve I53 which is open at that time, into the piston chamber I51.

It will be noted that the bottom portion of the piston I56 has only one half of the area of the top portion, and, therefore, if the pressure of the air in the chamber I82 exceeds one-half of the pressure of air in the passage I80, the piston I56 goes down, the valve I54 closes and remains closed until the pressure of the air in the passage I83 is lowered to less than one half of the pres- I speed of application of the brakes may be adjusted to suit the particular conditions, and the air pressure applied on the brake operating mechanism may be cut to one half of the pressure in the main line.

As it has been heretofore explained, the air brake is actuated by the decrease of the air pressure in the main line 2 of a train. But if a. train-is sufliciently long, it will take considerable'time .-until the air. pressure the rmain line drops down to a desired operative level throughout the length .of the train. .Eurthermore, the decrease of the air pressure in'the main line will be gradual and will afiect cars gradually, beginning with the cars closest to the engine.

In order to facilitate the operation of the. air brakes, andforce the brakes to act simultaneously, I provide a valve mechanism 200 for additional discharge of the pressure in the main line 2, whenever .said pressure .falls down to a predetermined pressure. The valve mechanism 200 consistsof a housing 20I which has a plurality of discharge openings'203. The housing 20I ;is in communication with the passage 204 terminating with the aperture 60 in the bushing 33. When the main piston 4I moves .to the left looking at Fig. 6 due to the change in air pressure in the tank 35, the aperture 60 registers with the aperture 55 in the sliding valve 45 thus permitting the compressed air to pass from the valve chamber32 to the valve mechanism 200.

The latter includes a valve 20'! having a starshaped stem 208 and a broad shoulder 2Il on the valve proper. Aspring 2I3 yieldably holds said valve against the seat 2I4. When the compressed air passes to the valve 207 under pressure sufficient to raise the valve slightly, the air immediately passes to the shoulder 2H and, acting on a greater area, quickly moves said valve against the stop .2I2 and beyond the discharge openings 203, through which the air is discharged into'the atmosphere. The spring U3 is of such force as to be initially compressed by the pressure somewhatless than the standard pressure and higher than the operating pressure and to close the valve when the air pressure drops to the operating pressure. By additional discharge of air from all the brake actuating mechanisms I and from the main line 2 of a train, the former will beforced to actuate and the brakeswill be immediately applied.

'The operation of the device may be ,divided into the following steps: charging of the device withcompressed air, application of the brakes,

supplying the brake mechanism and the supply tank with compressed .air when brakes are applied, and the release of the brakes.

The standard pressure which is maintained in the main lineis preferably equal to 75.pounds. When the compressed-air is introduced into the main line 2 and therefrom into the chamber 32, it forces the piston M to the 'extremeright, as shown in Fig. 6, and, as it has been previously explained, enters the auxiliary tank 68 and the chamber II and forces the pistons I2 and T1 and the valve I9 to the extreme left, thus opening a passage for the air from the brake cylinder 8 into the atmosphere.

At the same time the compressed air flows from the chamber 32 through the passage 55 in the sliding valve 45, the aperture 62 in the bushing 33, the passage 205, into the piston chamber I05 of the second actuator 3I and forces the piston I06 into the position shown in Fig. 9. There is a groove 220 provided on the inner wall of said chamber I05, extending less than a'half of the length of said chamber, through which groove the air passes from the chamber I05 around and on the other side of the piston I05. 'Another groove 22I is cut on .a valve portion 223, formed on thesideof the piston I06, facing the bushing 'IOI, "for the purpose of closing the nism 6 and actuates the latter.

same. The air passes through said groove 22I into the valve chamber I00 and therefrom into the supply tank 4.

An aperture 222 is provided in the bushing IOI which leads to a spring pressed valve 224. The compressedair lifts said valve 224 and passes to a passage 225 and through the same into the tank 350i the first actuator 30. The compressed air from the valve 224 also passes into a passage 225 around the bushing IM to the aperture I25, which is closed at that time. Therefore, equal air pressure is established on both sides of each of the pistons 4| and I06, the brake mechanism'6 communicates with the atmosphere in two ways, as has been heretofore described in detail, and the supply tank 4 is charged with compressed air.

To actuate the brakes it is necessary to reduce the air pressure in the main line to an operating pressure which is preferably about pounds when full application of air brakes is desired, and is higher than that if partial application of braking power is intended. Figures 15 and 16 diagrammatically illustrate the position of various parts of the actuating mechanism I when the brakes are partially and fully applied, respectively.

When the air pressure in the main line 2 is reduced, the piston 4I, under the pressure of the compressed air in the tank 35, moves straight to the extreme left position, closing the bore 46 by the plunger 41 and pushing the sliding valve into the extreme left position. The passage 55 registers with the aperture and the air passes through the passage 204 to the valve mechanism 200 for additional discharge of air.

As has been heretofore explained, the valve 201 opens and lets the air pass to the atmosphere, thus reducing the pressure in the chamber 32, and, consequently, in the main line 2.

The passage 52 in the sliding valve 45 registers with the apertures 58 and 59 and the air from the auxiliary tank 68 and piston chamber 'Il, passes into the atmosphere through the passage I38. Thereupon the piston 12 moves to the extreme right position, looking on the Fig. 6, the valve 19 closes, and the air passage from the brake mechanism 6 to the atmosphere is cut off.

The air pressure in the auxiliary piston chamber I05 also decreases, as the latter is connected with the chamber 32 by means of the passage 285 and the aperture 62 which is now open. The compressed air in the supply tank 4 and in the chamber I00 pushes the piston I06 away from the bushing I 0|, thus cutting the groove 220 off the chamber I05, and the passage of the compressed air from the main line 2 into the supply tank 4 ceases.

The piston I06 is pushed by the compressed air in'the supply tank 4 certain distance away from the bushing IIlI depending upon the air pressure inthe main line 2. It is'shown in Fig. 15 in the .middle'of the pistonchamber I05, in which case the brakes are only partially applied, and in the'extreme left position in Fig. 16, when the brakes are fully applied. The plunger I II opens the entrance into the bore IIO,the opening II4 registers with the aperture IIS and I20, and the compressed 1 air passes from the supply tank 4 into the passage I13, through the stop-cock I52, into the space I3I, and to the brake mecha- If the air pressure in the tank ifalls slightly below the pressure in the main line 2, the piston I06 moves slightly to the left, thereby-closing the bore IIO by the plunger III, and the flow of air from thetank 4 to the brake mechanism 6 is cut off. At this time the mechanism 6 is also cut 01f from the atmosphere.

During the application of the brakes, the compressed air from the tank 35 is gradually discharged through the passage 225, above the valve 224, through the passage 226, aperture I25, passage II6, into the chamber I which communicates directly with the tank 4.

Therefore, the air pressure on the left side of the piston 4|, looking on the Fig. 6, is equal to the pressure in the main line 2, and on the right side of said piston to the pressure in the supply tank 4; and the air pressure on the left side of the piston I06, looking on the Fig. 9 is equal to the pressure in said supply tank, and on the right side, to the pressure of the main line 2. Whenever the relative pressures in the main line 2 and the supply tank 4 change, the pistons 4| and I06 change their positions accordingly.

If it is desirable to apply the brakes for a considerable period of time with substantially the same force, it is necessaryto supply the brake mechanism 6 with compressed air, otherwise the supply tank 4 may become exhausted through leakage in said brake mechanism and the brakes thus rendered inoperative.

Fig. 17 diagrammatically shows the position of Various parts of the actuating mechanism when the compressed air is supplied to the supply tank 4 during the braking operation. It is necessary to reduce the pressure in the main line 2 to the operating pressure, preferably 55 pounds, and maintain the same for the period of the braking operation.

Asshown in Fig. 2, the main line 2 is connected to a standard operating valve 250, having a handle 25I. By manipulating the handle 25I the air pressure in the line 2 may be decreased, orincreased, to various pressures, or the compressed airmay be by-passed through a pipe 253 and a constant pressure valve 254 which will maintain the standard pressure of preferably '75 pounds-in said main line 2. The compressed air is delivered to the operating valve 250 by a pipe 255 from the main supply tank 256. A by-pass pipe 258, a constant pressure valve 259 and a three-way valve 260 are arranged in connection with the pipe 255, by means of which the air from the main supply tank 256 may be passed through said pipe 258, valve 259 and valve 260 into the main line 2, in which case a flow of compressed air at operating pressure of preferably 55 pounds will be maintained in said line 2. If the brakes have been applied for a considerable period of time and due to the leakage of air the pressure inthe brake mechanism decreases, and becomes less than that'in the mainline 2, the piston I06 of the second actuator 3| moves to the bushing I M and closes the same, and the piston 4| is slightly moved away from the bushing 33. There- 'upon an air passage from the main line 2 to the brake mechanism 6 is established as follows: the main line 2, chamber 32, bore 46, passage 50, aperture 51, passage I28, passage I2I, aperture I22, passage II5, aperture I23, passage I30, area I3I, pipe I, to the brake mechanism 6.

Compressed air from the chamber 32 also passes to the supply tank 4 through the aperture 62, passage 205, chamber I05, grooves 220 and 22I, chamber I00, pipe 5, to the tank 4. Therefore, the brake mechanism 6 and the supply tank 4 are supplied with the compressed air from the main line 2 as long as the pressure in the main line is maintained at the constant operating pressure, and'the brakes may be applied for any length of time without any danger of exhausting the supply tank, and rendering the brakes inoperative.

An operator may either release the brakes com pletely and immediately, or gradually, step by step. For the complete release of thebrakes, the pressure in the main line 2 isrraised to the standard pressure. In this case the piston 4| travels to the extreme right position, looking at Fig. 6, the pistons I2 and 71 are actuated, and the valve I9 opens, thus releasingthe air from the brake mechanism 6. Communication between the supply tank 4 and the mechanism 6 is cut oil".

If it is desired to release the brakes to a certain degree only, the pressure in the main line is raised to a certain level above the operating and below the standard pressure. Then the .piston 41 travels to the right, looking at Fig. 18," approximately a half of the length of the chamber 36. The plunger 4! opens the passage into the bore 46 and the compressed air passes from the chamber 32'into said bore 46, passage 48, aperture 58, passage'66, passage I0, chamber II, and will force the pistons I2 and IT to the left some distance and open the valve I9. The air from the brake mechanism 6 will pass to the atmosphere the following'way: through the space I3I, passage I30, aperture I23, passage I I5, aperture I22, passages I21 and I28, chamber I6, valve I9, chamber I6, opening 85 to the atmosphere. When certain amountof air is released from the brake mechanism 6, the air pressure in the chamber I6 will be reduced and the spring 80 willmove the piston 11 to the leftlooking on the Fig. '6, thereby closing the valve 19. If further release of the brakes is desirable, the pressure in the main line 2 is increased, and the pistons I2 and 11 will move again to the left and open the valve I9. More air will be released'from the brake mechanism 6 until the piston TI again moves to the left and closes the valve I9.

This process may be repeated over andover again until the piston I2 will reach its extreme left position. Therefore the release of the brakes may be regulated by the air pressure in the main line 2, and the brakes will be held in the desired position any length of time.

From the above description follows that my air brake will act quickly and simultaneously over the whole length of a train because of the mechanism 200 for additional discharge of the pressure in the main line. The mechanism I50 permits individual adjustment of application of the brake mechan'isms6 depending upon the load and type of a particular car and the speed of a train. The brakes may be gradually released to any desired'degree and will be held in such position for any length'of time. Compressed air will 1 be supplied to the supply tank 4 from the main air pressure in the mainline :decreases,: and ,for restricting the passage'oi compressed air from said tank into said. brake mechanism: when, the pressure of air in the main line raises to said standard pressure; a valve adapted to open and to close at certain air pressures; and means for bringing said valve in communication with said main line when the air pressure in the latter decreases to a certain level, so as to discharge said compressed air fromthe mainline into the atmosphere and thereby reduce the pressure thereof tea certain level.

2. In an air brake system a combination of a main line normally carrying compressed air at a certain standard pressure, a brake mechanism, and an actuating mechanism operable by the air pressure changes in the main line and adapted to actuate saidbrake mechanism when the pressure in the main line drops'to a certain'operating pressure which is lower than said standard pressure; with a device. for additional discharge of compressedair adapted to be put by saidactuating mechanism in communication with the main line when the air pressure therein begins to drop, said device being adapted to reduce the pressure in said main line to said operating level by discharging the compressed air directly into the atmosphere.

3. In an air brake system a combination of a main line normally carrying compressed air at a certain standard pressure, a brake mechanism, andv an actuating mechanism operable by the air pressure changes in the main line and adapted to actuate said brake mechanism when the pressure in the mainline drops to a certain operating pressure which is lowerthan said standard pressure; with a device for additional discharge:of compressed air adapted. toibe put. by saidactuating mechanism in'communicatiomwith'the main line when the air pressure therein begins to drop; said device comprising a spring pressed valve adapted to reduce the air pressure in said main line to said operating level.

4. In an air brake system including a main line carrying compressed air at a standard pressure and a brake mechanism operable by compressed air; means for graduated intermittent release of the brakes comprising a first, spring pressed, piston adapted to be actuated by the compressed air in the main line, a second piston adapted to be actuated by the compressed air in the brake mechanism; means for yieldingly holding said pistons apart, and means carried by the second piston for releasing the compressed air from the brake mechanism depending upon the air pressure in the main line.

5. In an air brake system including a main line carrying compressed air at a standard pressure and a brake mechanism operable by compressed air; means forgraduated intermittent release of the brakes comprising a first, spring pressed, piston adapted to be actuated by the compressed air in the main line, a second piston adapted to be actuated by the compressed air in the brake mechanism; means for yieldingly holding said pistons apart, and a valve arranged in the second piston adapted to release the compressed air from the brake mechanism depending upon the air pressure in the main line.

6. In an air brake system including a main line carrying compressed air at a standard pressure and a brake mechanism o erable by compressed air; means for graduated intermittent release of the brakes comprising a chamber adapted to communicate with the main line; a spring pressed piston in said chamberadapted to be actuated by the compressedair in the main line; asecond chamber formed adjacent the first mentioned chamber adapted to be placed in communication with the brake mechanism; a second piston in said second chamber adapted to be actuated by the compressed air in the brake mechanism; means for yieldingly holding the first mentioned piston and the second piston apart; and a valve arranged in the second piston for releasing the compressed air from the second chamber depending upon the pressure of the compressed air in the first mentioned chamber.

7. In an air brake system including a main line carrying compressed air at a standard pressure and a brake mechanism operable by compressed air; means for graduated intermittent release of the brakes comprising two pistons one of which is adapted to be subjected to air pressure of the main line and the other to the air pressure of the brake mechanism; yieldable means for holding the pistons apart; means carried by the second mentioned piston and operable by the first mentioned piston for release of the air pressure in the brake mechanism.

8. In an air brake system a combination of a main line normally carrying compressed air at a certain standard pressure. a brake mechanism, and an actuating mechanism operable by the air pressure changes in the main line and adapted to actuate said brake mechanism when the pressure in the main line drops to a certain operating pressure which is lower than said standard pressure; with a device for additional discharge of compressed air comprising a housing having a passage therein adapted to be put by the actuating mechanism in communication with the main line whenever the air pressure in the latter begins to drop; a spring'pressed' valve having a frustro-conical portion and a flat shoulder therearound, said passage having formed therein a corresponding conical seat and a fiat ring-shaped shoulder therearound upon which said valve normally rests.

9. A device for release of compressed air to a certain pressure, comprising a housing having a passage therein a valve arranged in said passage, said valve having a central frustro-conical portion and a flat shoulder therearound, said passage having a valve seat arranged therein, a spring pressing said valve upon said seat, and means adapted to admit compressed air into said passage.

10. In an' air brake system having a braking mechanism, a supply tank normally charged with compressed air, and an actuating mechanism adapted to put said braking mechanism and supply tank in communication; means for selecting the speed of application of the brakes by said braking mechanism comprising a stop-cock having various passages therein, a valve communicating with said stop-cock, a piston adapted to actuate'said valveso as to pass a greater amount of air in the beginning of a braking operation and a smaller amount of air when pressure in braking mechanism reaches certain level, a second valve connected with the stopcock, a second piston, the latter having different areas exposed to the pressure of air passing through said stop-cock and arranged to control the second valve so as to pass air therethrough at the pressure equal to a fraction of that in the supply tank.

11. In an air brake system having a braking mechanism, a supply tank normally charged with ation and a smaller amount of air when pressure 10 in braking mechanism reaches certain level, a second valve connected with said stop-cock, a second piston having two different areas so arranged as to be exposed to the pressure of air from the supply tank, said second piston being adapted to control said second valve as to pass the air therethrough at a pressure equal to onehalf of that in the supply tank.

DMITRI ANDREIEVICH KALOSHIN. 

